Abstract
Four different double-compression CO2 transcritical refrigeration cycles are studied: double-compression external intercooler cycle (DCEI), double-compression external intercooler cycle with an expander (DCEIE), double-compression flash intercooler cycle (DCFI), double-compression flash intercooler cycle with an expander (DCFIE). The results showed that the optimum gas cooler pressure and optimum intermediate pressure of the flash intercooler cycles are lower than that of the external intercooler cycle. The use of an expander in the DCEI cycle leads to a decrease of the optimum gas cooler pressure and little variation of the optimum intermediate pressure. However, the replacement of the throttle valve with an expander in the DCFI cycle results in little variation of the optimal gas cooler pressure and an increase of the optimum intermediate pressure. The DCFI cycle outperforms the DCEI cycle under all the chosen operating conditions. The DCEIE cycle outperforms the DCFIE cycle when the evaporating temperature exceeds 0 °C or the gas cooler outlet temperature surpasses 35 °C. When the gas cooler exit temperature varies from 32 °C to 48 °C, the DCEI cycle, DCEIE cycle, DCFI cycle and DCFIE cycle yield averaged 4.6%, 29.2%, 12.9% and 22.3% COP improvement, respectively, over the basic cycle.
Highlights
Refrigerant alternatives and saving energy have become hot topics in the field of refrigeration and air conditioning
More COP improvement is gained by the use of an expander to replace the throttle valve for the double-compression external intercooler cycle (DCEI) cycle compared to the double-compression flash intercooler cycle (DCFI) cycle
When the gas cooler exit temperature varies from 32 °C to 48 °C, DCEI cycle, double-compression external intercooler cycle with an expander (DCEIE) cycle, DCFI cycle, and double-compression flash intercooler cycle with an expander (DCFIE) cycle yields average 4.6%, 29.2%, 12.9% and 22.3% COP improvement over the basic cycle, respectively
Summary
Refrigerant alternatives and saving energy have become hot topics in the field of refrigeration and air conditioning. Cho et al [8] experimentally found that the double-compression transcritical CO2 cycle with gas injection yields a 16.5% improvement of the cooling COP over that of the two-stage non-injection cycle. Theoretically found that the double-stage external intercooler cycle with an expander can achieve an improvement of up to 42% in COP over the basic cycle. Zhili et al [19] investigated the performance of several different expander-compressor arrangements for the double-stage external intercooler cycle, and found that the cycle with an expressor as the main compressor can yield the highest COP. The thermodynamic model of the double-compression CO2 cycles with and without an expander was developed Based on this model, a steady-state simulation of the systems has been carried. The performance improvement of each of the double-compression cycle technologies was evaluated
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